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 *modification, are permitted provided that the following conditions are met:
 *     * Redistributions of source code must retain the above copyright notice,
 *this list of conditions and the following disclaimer.
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 *notice, this list of conditions and the following disclaimer in the
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/*! \file
    \brief Definitions for GEMM structures
*/

#pragma once

#include "cutlass/cutlass.h"
#include "cutlass/numeric_types.h"
#include "cutlass/arch/arch.h"
#include "cutlass/arch/mma.h"
#include "cutlass/arch/wmma.h"

#include "cutlass/gemm/gemm.h"
#include "cutlass/epilogue/thread/linear_combination.h"
#include "cutlass/epilogue/thread/linear_combination_clamp.h"

////////////////////////////////////////////////////////////////////////////////

namespace cutlass {
namespace gemm {
namespace device {

////////////////////////////////////////////////////////////////////////////////

template <typename OperatorClass, typename ArchTag, typename ElementA,
          typename ElementB, typename ElementC, typename ElementAccumulator>
struct DefaultGemmConfiguration;

////////////////////////////////////////////////////////////////////////////////

template <typename ArchTag, typename ElementA, typename ElementB,
          typename ElementC, typename ElementAccumulator>
struct DefaultGemmConfiguration<arch::OpClassSimt, ArchTag, ElementA, ElementB,
                                ElementC, ElementAccumulator> {
    static int const kAlignmentA = 1;
    static int const kAlignmentB = 1;
    using ThreadblockShape = GemmShape<128, 128, 8>;
    using WarpShape = GemmShape<32, 64, 8>;
    using InstructionShape = GemmShape<1, 1, 1>;
    static int const kStages = 2;

    using EpilogueOutputOp =
            epilogue::thread::LinearCombination<ElementC, 1, ElementAccumulator,
                                                ElementAccumulator>;

    using Operator = arch::OpMultiplyAdd;
};

////////////////////////////////////////////////////////////////////////////////

template <typename ArchTag, typename ElementC>
struct DefaultGemmConfiguration<arch::OpClassSimt, ArchTag, int8_t, int8_t,
                                ElementC, int32_t> {
    static int const kAlignmentA = 4;
    static int const kAlignmentB = 4;
    using ThreadblockShape = GemmShape<128, 128, 32>;
    using WarpShape = GemmShape<32, 64, 32>;
    using InstructionShape = GemmShape<1, 1, 4>;
    static int const kStages = 2;

    using EpilogueOutputOp =
            epilogue::thread::LinearCombinationClamp<ElementC, 1, int32_t,
                                                     float>;

    using Operator = arch::OpMultiplyAdd;
};

////////////////////////////////////////////////////////////////////////////////

template <typename ArchTag, typename ElementA, typename ElementB,
          typename ElementC, typename ElementAccumulator>
struct DefaultGemmConfiguration<arch::OpClassWmmaTensorOp, ArchTag, ElementA,
                                ElementB, ElementC, ElementAccumulator> {
    static int const kAlignmentA = 128 / sizeof_bits<ElementA>::value;
    static int const kAlignmentB = 128 / sizeof_bits<ElementB>::value;

    static int const kStages = 2;

    using EpilogueOutputOp = epilogue::thread::LinearCombination<
            ElementC, 128 / sizeof_bits<ElementC>::value, ElementAccumulator,
            ElementAccumulator>;

    using Operator = arch::OpMultiplyAdd;
};

////////////////////////////////////////////////////////////////////////////////

template <typename ElementA, typename ElementB, typename ElementC,
          typename ElementAccumulator>
struct DefaultGemmConfiguration<arch::OpClassTensorOp, arch::Sm70, ElementA,
                                ElementB, ElementC, ElementAccumulator> {
    static int const kAlignmentA = 128 / sizeof_bits<ElementA>::value;
    static int const kAlignmentB = 128 / sizeof_bits<ElementB>::value;

    using ThreadblockShape = GemmShape<128, 256, 32>;
    using WarpShape = GemmShape<64, 64, 32>;
    using InstructionShape = GemmShape<16, 16, 4>;
    static int const kStages = 2;

    using EpilogueOutputOp = epilogue::thread::LinearCombination<
            ElementC, 128 / sizeof_bits<ElementC>::value, ElementAccumulator,
            ElementAccumulator>;

    using Operator = arch::OpMultiplyAdd;
};

////////////////////////////////////////////////////////////////////////////////

template <typename ElementA, typename ElementB, typename ElementC,
          typename ElementAccumulator>
struct DefaultGemmConfiguration<arch::OpClassTensorOp, arch::Sm75, ElementA,
                                ElementB, ElementC, ElementAccumulator> {
    static int const kAlignmentA = 128 / sizeof_bits<ElementA>::value;
    static int const kAlignmentB = 128 / sizeof_bits<ElementA>::value;
    using ThreadblockShape = GemmShape<128, 256, 32>;
    using WarpShape = GemmShape<64, 64, 32>;
    using InstructionShape = GemmShape<16, 8, 8>;
    static int const kStages = 2;

    using EpilogueOutputOp = epilogue::thread::LinearCombination<
            ElementC, 128 / sizeof_bits<ElementC>::value, ElementAccumulator,
            ElementAccumulator>;

    using Operator = typename platform::conditional<
            (platform::is_same<ElementA, int8_t>::value ||
             platform::is_same<ElementA, int4b_t>::value ||
             platform::is_same<ElementA, uint8_t>::value ||
             platform::is_same<ElementA, uint4b_t>::value),
            arch::OpMultiplyAddSaturate, arch::OpMultiplyAdd>::type;
};

////////////////////////////////////////////////////////////////////////////////

template <typename ElementC>
struct DefaultGemmConfiguration<arch::OpClassTensorOp, arch::Sm75, int8_t,
                                int8_t, ElementC, int32_t> {
    static int const kAlignmentA = 128 / sizeof_bits<int8_t>::value;
    static int const kAlignmentB = 128 / sizeof_bits<int8_t>::value;

    using ThreadblockShape = GemmShape<128, 256, 64>;
    using WarpShape = GemmShape<64, 64, 64>;
    using InstructionShape = GemmShape<8, 8, 16>;
    static int const kStages = 2;

    using EpilogueOutputOp = epilogue::thread::LinearCombinationClamp<
            ElementC, 128 / sizeof_bits<ElementC>::value, int32_t, float>;

    using Operator = arch::OpMultiplyAddSaturate;
};

////////////////////////////////////////////////////////////////////////////////

template <typename ElementC>
struct DefaultGemmConfiguration<arch::OpClassTensorOp, arch::Sm75, int8_t,
                                uint8_t, ElementC, int32_t> {
    static int const kAlignmentA = 128 / sizeof_bits<int8_t>::value;
    static int const kAlignmentB = 128 / sizeof_bits<uint8_t>::value;

    using ThreadblockShape = GemmShape<128, 256, 64>;
    using WarpShape = GemmShape<64, 64, 64>;
    using InstructionShape = GemmShape<8, 8, 16>;
    static int const kStages = 2;

    using EpilogueOutputOp = epilogue::thread::LinearCombinationClamp<
            ElementC, 128 / sizeof_bits<ElementC>::value, int32_t, float>;

    using Operator = arch::OpMultiplyAddSaturate;
};

////////////////////////////////////////////////////////////////////////////////

template <typename ElementC>
struct DefaultGemmConfiguration<arch::OpClassTensorOp, arch::Sm75, uint8_t,
                                int8_t, ElementC, int32_t> {
    static int const kAlignmentA = 128 / sizeof_bits<uint8_t>::value;
    static int const kAlignmentB = 128 / sizeof_bits<int8_t>::value;

    using ThreadblockShape = GemmShape<128, 256, 64>;
    using WarpShape = GemmShape<64, 64, 64>;
    using InstructionShape = GemmShape<8, 8, 16>;
    static int const kStages = 2;

    using EpilogueOutputOp = epilogue::thread::LinearCombinationClamp<
            ElementC, 128 / sizeof_bits<ElementC>::value, int32_t, float>;

    using Operator = arch::OpMultiplyAddSaturate;
};

////////////////////////////////////////////////////////////////////////////////

template <typename ElementC>
struct DefaultGemmConfiguration<arch::OpClassTensorOp, arch::Sm75, uint8_t,
                                uint8_t, ElementC, int32_t> {
    static int const kAlignmentA = 128 / sizeof_bits<uint8_t>::value;
    static int const kAlignmentB = 128 / sizeof_bits<uint8_t>::value;

    using ThreadblockShape = GemmShape<128, 256, 64>;
    using WarpShape = GemmShape<64, 64, 64>;
    using InstructionShape = GemmShape<8, 8, 16>;
    static int const kStages = 2;

    using EpilogueOutputOp = epilogue::thread::LinearCombinationClamp<
            ElementC, 128 / sizeof_bits<ElementC>::value, int32_t, float>;

    using Operator = arch::OpMultiplyAddSaturate;
};

////////////////////////////////////////////////////////////////////////////////

template <typename ElementC>
struct DefaultGemmConfiguration<arch::OpClassTensorOp, arch::Sm75, int4b_t,
                                int4b_t, ElementC, int32_t> {
    static int const kAlignmentA = 128 / sizeof_bits<int4b_t>::value;
    static int const kAlignmentB = 128 / sizeof_bits<int4b_t>::value;

    using ThreadblockShape = GemmShape<128, 256, 128>;
    using WarpShape = GemmShape<64, 64, 128>;
    using InstructionShape = GemmShape<8, 8, 32>;
    static int const kStages = 2;

    using EpilogueOutputOp = epilogue::thread::LinearCombinationClamp<
            ElementC, 128 / sizeof_bits<ElementC>::value, int32_t, float>;

    using Operator = arch::OpMultiplyAddSaturate;
};

////////////////////////////////////////////////////////////////////////////////

template <typename ElementC>
struct DefaultGemmConfiguration<arch::OpClassTensorOp, arch::Sm75, int4b_t,
                                uint4b_t, ElementC, int32_t> {
    static int const kAlignmentA = 128 / sizeof_bits<int4b_t>::value;
    static int const kAlignmentB = 128 / sizeof_bits<uint4b_t>::value;

    using ThreadblockShape = GemmShape<128, 256, 128>;
    using WarpShape = GemmShape<64, 64, 128>;
    using InstructionShape = GemmShape<8, 8, 32>;
    static int const kStages = 2;

    using EpilogueOutputOp = epilogue::thread::LinearCombinationClamp<
            ElementC, 128 / sizeof_bits<ElementC>::value, int32_t, float>;

    using Operator = arch::OpMultiplyAddSaturate;
};

////////////////////////////////////////////////////////////////////////////////

template <typename ElementC>
struct DefaultGemmConfiguration<arch::OpClassTensorOp, arch::Sm75, uint4b_t,
                                int4b_t, ElementC, int32_t> {
    static int const kAlignmentA = 128 / sizeof_bits<uint4b_t>::value;
    static int const kAlignmentB = 128 / sizeof_bits<int4b_t>::value;

    using ThreadblockShape = GemmShape<128, 256, 128>;
    using WarpShape = GemmShape<64, 64, 128>;
    using InstructionShape = GemmShape<8, 8, 32>;
    static int const kStages = 2;

    using EpilogueOutputOp = epilogue::thread::LinearCombinationClamp<
            ElementC, 128 / sizeof_bits<ElementC>::value, int32_t, float>;

    using Operator = arch::OpMultiplyAddSaturate;
};

////////////////////////////////////////////////////////////////////////////////

template <typename ElementC>
struct DefaultGemmConfiguration<arch::OpClassTensorOp, arch::Sm75, uint4b_t,
                                uint4b_t, ElementC, int32_t> {
    static int const kAlignmentA = 128 / sizeof_bits<uint4b_t>::value;
    static int const kAlignmentB = 128 / sizeof_bits<uint4b_t>::value;

    using ThreadblockShape = GemmShape<128, 256, 128>;
    using WarpShape = GemmShape<64, 64, 128>;
    using InstructionShape = GemmShape<8, 8, 32>;
    static int const kStages = 2;

    using EpilogueOutputOp = epilogue::thread::LinearCombinationClamp<
            ElementC, 128 / sizeof_bits<ElementC>::value, int32_t, float>;

    using Operator = arch::OpMultiplyAddSaturate;
};

////////////////////////////////////////////////////////////////////////////////

template <typename ElementC>
struct DefaultGemmConfiguration<arch::OpClassTensorOp, arch::Sm75, uint1b_t,
                                uint1b_t, ElementC, int32_t> {
    static int const kAlignmentA = 128 / sizeof_bits<uint1b_t>::value;
    static int const kAlignmentB = 128 / sizeof_bits<uint1b_t>::value;

    using ThreadblockShape = GemmShape<128, 256, 512>;
    using WarpShape = GemmShape<64, 64, 512>;
    using InstructionShape = GemmShape<8, 8, 128>;
    static int const kStages = 2;

    using EpilogueOutputOp = epilogue::thread::LinearCombinationClamp<
            ElementC, 128 / sizeof_bits<ElementC>::value, int32_t, float>;

    using Operator = arch::OpXorPopc;
};

////////////////////////////////////////////////////////////////////////////////

template <typename ElementA, typename ElementB, typename ElementC,
          typename ElementAccumulator>
struct DefaultGemmConfiguration<arch::OpClassTensorOp, arch::Sm80, ElementA,
                                ElementB, ElementC, ElementAccumulator> {
    static int const kAlignmentA = 128 / sizeof_bits<ElementA>::value;
    static int const kAlignmentB = 128 / sizeof_bits<ElementA>::value;

    using ThreadblockShape = GemmShape<128, 256, 64>;
    using WarpShape = GemmShape<64, 64, 64>;
    using InstructionShape = GemmShape<16, 8, 16>;
    static int const kStages = 3;

    using EpilogueOutputOp = epilogue::thread::LinearCombination<
            ElementC, 128 / sizeof_bits<ElementC>::value, ElementAccumulator,
            ElementAccumulator>;

    using Operator = typename platform::conditional<
            (platform::is_same<ElementA, int8_t>::value ||
             platform::is_same<ElementA, int4b_t>::value ||
             platform::is_same<ElementA, uint8_t>::value ||
             platform::is_same<ElementA, uint4b_t>::value),
            arch::OpMultiplyAddSaturate, arch::OpMultiplyAdd>::type;
};

////////////////////////////////////////////////////////////////////////////////
template <typename ElementC, typename ElementAccumulator>
struct DefaultGemmConfiguration<arch::OpClassTensorOp, arch::Sm80, double,
                                double, ElementC, ElementAccumulator> {
    static int const kAlignmentA = 1;
    static int const kAlignmentB = 1;

    using ThreadblockShape = GemmShape<128, 256, 64>;
    using WarpShape = GemmShape<64, 64, 64>;
    using InstructionShape = GemmShape<16, 8, 16>;
    static int const kStages = 3;

    using EpilogueOutputOp = epilogue::thread::LinearCombination<
            ElementC, 128 / sizeof_bits<ElementC>::value, ElementAccumulator,
            ElementAccumulator>;

    using Operator = arch::OpMultiplyAdd;
};

template <>
struct DefaultGemmConfiguration<arch::OpClassTensorOp, arch::Sm80,
                                complex<double>, complex<double>,
                                complex<double>, complex<double>> {
    static int const kAlignmentA = 1;
    static int const kAlignmentB = 1;

    using ThreadblockShape = GemmShape<64, 64, 16>;
    using WarpShape = GemmShape<32, 32, 16>;
    using InstructionShape = GemmShape<8, 8, 4>;
    static int const kStages = 3;

    using EpilogueOutputOp = epilogue::thread::LinearCombination<
            complex<double>, 1, complex<double>, complex<double>>;

    using Operator = arch::OpMultiplyAddComplex;
};

////////////////////////////////////////////////////////////////////////////////

template <typename ElementC>
struct DefaultGemmConfiguration<arch::OpClassTensorOp, arch::Sm80, int8_t,
                                int8_t, ElementC, int32_t> {
    static int const kAlignmentA = 128 / sizeof_bits<int8_t>::value;
    static int const kAlignmentB = 128 / sizeof_bits<int8_t>::value;

    using ThreadblockShape = GemmShape<128, 256, 64>;
    using WarpShape = GemmShape<64, 64, 64>;
    using InstructionShape = GemmShape<16, 8, 32>;
    static int const kStages = 3;

    using EpilogueOutputOp = epilogue::thread::LinearCombinationClamp<
            ElementC, 128 / sizeof_bits<ElementC>::value, int32_t, float>;

    using Operator = arch::OpMultiplyAddSaturate;
};

////////////////////////////////////////////////////////////////////////////////

template <typename ElementC>
struct DefaultGemmConfiguration<arch::OpClassTensorOp, arch::Sm80, int8_t,
                                uint8_t, ElementC, int32_t> {
    static int const kAlignmentA = 128 / sizeof_bits<int8_t>::value;
    static int const kAlignmentB = 128 / sizeof_bits<uint8_t>::value;

    using ThreadblockShape = GemmShape<128, 256, 64>;
    using WarpShape = GemmShape<64, 64, 64>;
    using InstructionShape = GemmShape<16, 8, 32>;
    static int const kStages = 3;

    using EpilogueOutputOp = epilogue::thread::LinearCombinationClamp<
            ElementC, 128 / sizeof_bits<ElementC>::value, int32_t, float>;

    using Operator = arch::OpMultiplyAddSaturate;
};

////////////////////////////////////////////////////////////////////////////////

template <typename ElementC>
struct DefaultGemmConfiguration<arch::OpClassTensorOp, arch::Sm80, uint8_t,
                                int8_t, ElementC, int32_t> {
    static int const kAlignmentA = 128 / sizeof_bits<uint8_t>::value;
    static int const kAlignmentB = 128 / sizeof_bits<int8_t>::value;

    using ThreadblockShape = GemmShape<128, 256, 64>;
    using WarpShape = GemmShape<64, 64, 64>;
    using InstructionShape = GemmShape<16, 8, 32>;
    static int const kStages = 3;

    using EpilogueOutputOp = epilogue::thread::LinearCombinationClamp<
            ElementC, 128 / sizeof_bits<ElementC>::value, int32_t, float>;

    using Operator = arch::OpMultiplyAddSaturate;
};

////////////////////////////////////////////////////////////////////////////////

template <typename ElementC>
struct DefaultGemmConfiguration<arch::OpClassTensorOp, arch::Sm80, uint8_t,
                                uint8_t, ElementC, int32_t> {
    static int const kAlignmentA = 128 / sizeof_bits<uint8_t>::value;
    static int const kAlignmentB = 128 / sizeof_bits<uint8_t>::value;

    using ThreadblockShape = GemmShape<128, 256, 64>;
    using WarpShape = GemmShape<64, 64, 64>;
    using InstructionShape = GemmShape<16, 8, 32>;
    static int const kStages = 3;

    using EpilogueOutputOp = epilogue::thread::LinearCombinationClamp<
            ElementC, 128 / sizeof_bits<ElementC>::value, int32_t, float>;

    using Operator = arch::OpMultiplyAddSaturate;
};

////////////////////////////////////////////////////////////////////////////////

template <typename ElementC>
struct DefaultGemmConfiguration<arch::OpClassTensorOp, arch::Sm80, int4b_t,
                                int4b_t, ElementC, int32_t> {
    static int const kAlignmentA = 128 / sizeof_bits<int4b_t>::value;
    static int const kAlignmentB = 128 / sizeof_bits<int4b_t>::value;

    using ThreadblockShape = GemmShape<128, 256, 128>;
    using WarpShape = GemmShape<64, 64, 128>;
    using InstructionShape = GemmShape<16, 8, 64>;
    static int const kStages = 3;

    using EpilogueOutputOp = epilogue::thread::LinearCombinationClamp<
            ElementC, 128 / sizeof_bits<ElementC>::value, int32_t, float>;

    using Operator = arch::OpMultiplyAddSaturate;
};

////////////////////////////////////////////////////////////////////////////////

template <typename ElementC>
struct DefaultGemmConfiguration<arch::OpClassTensorOp, arch::Sm80, int4b_t,
                                uint4b_t, ElementC, int32_t> {
    static int const kAlignmentA = 128 / sizeof_bits<int4b_t>::value;
    static int const kAlignmentB = 128 / sizeof_bits<uint4b_t>::value;

    using ThreadblockShape = GemmShape<128, 256, 128>;
    using WarpShape = GemmShape<64, 64, 128>;
    using InstructionShape = GemmShape<16, 8, 64>;
    static int const kStages = 3;

    using EpilogueOutputOp = epilogue::thread::LinearCombinationClamp<
            ElementC, 128 / sizeof_bits<ElementC>::value, int32_t, float>;

    using Operator = arch::OpMultiplyAddSaturate;
};

////////////////////////////////////////////////////////////////////////////////

template <typename ElementC>
struct DefaultGemmConfiguration<arch::OpClassTensorOp, arch::Sm80, uint4b_t,
                                int4b_t, ElementC, int32_t> {
    static int const kAlignmentA = 128 / sizeof_bits<uint4b_t>::value;
    static int const kAlignmentB = 128 / sizeof_bits<int4b_t>::value;

    using ThreadblockShape = GemmShape<128, 256, 128>;
    using WarpShape = GemmShape<64, 64, 128>;
    using InstructionShape = GemmShape<16, 8, 64>;
    static int const kStages = 3;

    using EpilogueOutputOp = epilogue::thread::LinearCombinationClamp<
            ElementC, 128 / sizeof_bits<ElementC>::value, int32_t, float>;

    using Operator = arch::OpMultiplyAddSaturate;
};

////////////////////////////////////////////////////////////////////////////////

template <typename ElementC>
struct DefaultGemmConfiguration<arch::OpClassTensorOp, arch::Sm80, uint4b_t,
                                uint4b_t, ElementC, int32_t> {
    static int const kAlignmentA = 128 / sizeof_bits<uint4b_t>::value;
    static int const kAlignmentB = 128 / sizeof_bits<uint4b_t>::value;

    using ThreadblockShape = GemmShape<128, 256, 128>;
    using WarpShape = GemmShape<64, 64, 128>;
    using InstructionShape = GemmShape<16, 8, 64>;
    static int const kStages = 3;

    using EpilogueOutputOp = epilogue::thread::LinearCombinationClamp<
            ElementC, 128 / sizeof_bits<ElementC>::value, int32_t, float>;

    using Operator = arch::OpMultiplyAddSaturate;
};

////////////////////////////////////////////////////////////////////////////////

template <typename ElementC>
struct DefaultGemmConfiguration<arch::OpClassTensorOp, arch::Sm80, uint1b_t,
                                uint1b_t, ElementC, int32_t> {
    static int const kAlignmentA = 128 / sizeof_bits<uint1b_t>::value;
    static int const kAlignmentB = 128 / sizeof_bits<uint1b_t>::value;

    using ThreadblockShape = GemmShape<128, 256, 512>;
    using WarpShape = GemmShape<64, 64, 512>;
    using InstructionShape = GemmShape<16, 8, 256>;
    static int const kStages = 3;

    using EpilogueOutputOp = epilogue::thread::LinearCombinationClamp<
            ElementC, 128 / sizeof_bits<ElementC>::value, int32_t, float>;

    using Operator = arch::OpMultiplyAdd;
};

////////////////////////////////////////////////////////////////////////////////

////////////////////////////////////////////////////////////////////////////////
}  // namespace device
}  // namespace gemm
}  // namespace cutlass

////////////////////////////////////////////////////////////////////////////////
